JP6763786B2 - Automatic release of pressure in soda machines - Google Patents

Description

The present invention relates generally to carbonation machines, especially to pressure relief.

Soda machines that carbonate beverages are known in the art. Most such household carbonaters are designed to be manually operated and are usually manually operated to release carbon dioxide (CO ₂ ) from an attached pressure cylinder into a bottle of water. It is equipped with an operation type gas release valve. Also, such machines typically include one or more safety pressure release valves designed to vent if excess pressure builds up during the carbonation process.

U.S. Pat. No. 8,920,860 U.S. Patent Application Publication No. 2013/00379969 U.S. Pat. No. 7,975,988

Here, according to a preferred embodiment of the present invention, a household carbonation system is provided. This system has a mechanical fixing part that fixes the bottle in the carbonation system during carbonation, and a pressure that is controlled and released after carbonation, and the bottle is released from the mechanical fixing part after the carbonation is completed. It has a gradual release section for delaying being done.

Further, according to a preferred embodiment of the invention, the system is also a carbonation arm connected to the housing of the system via a spring, which is capable of descending during carbonation and has a cam surface. A normal open valve; a normally open valve with a plunger that can be pressed by the cam surface during carbonation to seal the valve, and a stepwise release unit. After carbonation, the spring gradually raises the carbonation arm at a controlled speed to gradually release the pressed state of the plunger and gradually release the valve seal. Have.

Further, according to a preferred embodiment of the present invention, the damper is a viscous damper.

Further, according to a preferred embodiment of the invention, the system also has a bottle holder that holds the bottle during carbonation and a bottle holder to accept the bottle for carbonation and to release the bottle after carbonation. The mechanical fixation includes a recessed area where the bottle is in an upright position and the protrusion of the bottle holder is located when the carbonated arm is lowered, with a shaft that rotates at an angle. The area prevents the bottle holder from rotating about the axis when the carbonation arm is lowered.

Also, according to a preferred embodiment of the invention, the system also has an exhaust valve with an exhaust pin, which extends from the exhaust valve when pressure is applied to the exhaust valve and exhausts. The pin engages with the recessed region of the second cam surface when extended to prevent the bottle holder from rotating about the axis.

Here, according to a preferred embodiment of the present invention, a coupling system for a home carbonation machine is provided. The system has a bottle holder that holds the bottle during carbonation; a shaft that the bottle holder tilts and rotates to accept the bottle for carbonation and to release the bottle after carbonation; an exhaust pin. An exhaust valve, the exhaust pin extending from the exhaust valve when pressure is applied to the exhaust valve, and a cam surface having a recessed region; the exhaust pin is an exhaust pin. It has a cam surface that engages the recessed area when extended, and the engaged exhaust pin prevents the bottle holder from rotating about the axis.

The subject matter considered to be the present invention is specifically pointed out and clearly asserted in the conclusions of the present specification. However, the present invention is best understood by reference to the following detailed description read with the accompanying drawings regarding the operating mechanisms and methods, as well as the objectives, features and advantages of those operating mechanisms and operating methods. sell.

It is a schematic diagram of a household carbonation system configured and operating according to the present invention. FIG. 3 is an alternative view of the household carbonation system of FIG. 1 configured and operating in accordance with the present invention. FIG. 3 is an alternative view of the household carbonation system of FIG. 1 configured and operating in accordance with the present invention. It is a schematic diagram illustrating the usage of the mechanical fixing part in the household carbonation system of FIG. 1 that is configured and operates according to the present invention. It is a schematic diagram illustrating the usage of the mechanical fixing part in the household carbonation system of FIG. 1 that is configured and operates according to the present invention. It is a schematic diagram illustrating the usage of the damper used with the household carbonation system of FIG. 1 configured and operating according to the present invention. FIG. 5 is a schematic diagram illustrating how to use a damper used with the household carbonation system of FIG. 1 configured and operating in accordance with the present invention. FIG. 6 is a schematic representation of an alternative embodiment of a household carbonation system configured and operating in accordance with the present invention. FIG. 6 is a schematic representation of an alternative embodiment of a household carbonation system configured and operating in accordance with the present invention. It is the schematic of the household carbonation system which uses the features of each household carbonation system of FIG. 1, FIG. 5A, and FIG. 5B in combination.

For the sake of brevity and clarity, the elements shown in each figure are not necessarily drawn to the correct scale. For example, the size of some elements can be exaggerated relative to others for clarity. In addition, reference numbers may be repeated in multiple figures to point to corresponding or similar elements, where appropriate.

In the following detailed description, a number of specific details will be described for a complete understanding of the present invention. However, those skilled in the art will appreciate that the present invention can be practiced without these particular details. In other examples, known methods, procedures, and components are not described in detail so as not to obscure the invention.

Applicants have recognized that if a soda bottle is released from the carbonation system too soon after carbonation, the projectile effect can dangerously push the bottle out of the carbonation system. Also, if released early, carbonated water may be lost from the bottle as a result of excessive foaming from the bottle. Applicants also recognized that, for some users, the time it takes for the bottle to release pressure after carbonation may be important.

Applicants can also release the carbonated water bottle in stages after carbonation, and only after the bottle of carbonated water produced has been decompressed to atmospheric pressure. It was recognized that the above problems could be solved by doing so.

Here, reference is made to FIG. 1 illustrating the household carbonation system 100 according to the embodiment of the present invention. The household carbonation system 100 includes a stepwise release unit 10 and a mechanical fixing unit 15. The stepwise release unit 10 includes a carbonation arm 40 and a normally open valve 50. The normally open valve 50 may include a plunger 52. The carbonate arm 40 may include a cam surface 70, may be connected to a gas cylinder 12 at one end (via pin 8 (not shown)), and the other end. The portion may have a sliding portion 20 (also not shown) attached to the carbonation arm 40. As described in more detail below, the sliding section 20 may allow the user 5 to perform the carbonation process by lowering the carbonation arm 40 using the sliding section 20. .. The carbonation arm 40 may be connected to the housing (not shown) of the system 100 via a torsion spring 60. The spring 60 can push the carbonated arm 40 forward when swiveled and supported by the housing. The mechanical fixing portion 15 includes a recessed region 35 of the carbonation arm 40 and a protruding portion 25 of the bottle holder 80. FIG. 1 illustrates a system 100 in a pre-carbonated state in which the normally open valve 50 is open (the piston 52 is out) and the carbonation arm 40 is in the most upright position.

The tension of the spring 60 is such that when the user 5 pushes the sliding portion 20 (and the carbonated arm 40) downward and then releases the sliding portion 20, if there is no additional resistance, the spring 60, the carbonated arm 40, And it will be appreciated that the sliding portion 20 can be preset so that it can automatically return to its original position.

Also, as illustrated in FIGS. 2A and 2B referenced herein, the bottle 45 containing water can be initially tilted and attached to the bottle holder 80 via a forked clamp (not shown). Will be understood. When the carbonation arm 40 is in the dormant position, the bottle holder 80 can partially rotate about the shaft 55 (FIG. 1) in a tilting motion. This allows the bottle 45 to be tilted to be added and removed. The forked clamp 85 (not shown) and the normally open valve 50 are similar to the clamps and valves described in Patent Document 1 which are incorporated herein by reference and assigned to an assignee common to the present invention. Can be. Further, after the bottle 45 is attached to the bottle holder 80 and held in an upright position as illustrated in FIG. 2B, the user 5 can manually lower the sliding portion 20 to initiate the carbonation process. Will be understood.

Since the bottle holder 80 can be rotatable about the shaft 55 when it is not in the carbonation position, when the carbonation arm 40 is lowered, the protrusion 25 engages with the recessed region 35, thereby causing the bottle holder 80 to rotate. It will be appreciated that can be prevented from rotating freely around the shaft 55.

It will be appreciated that User 5 can determine the desired carbonation level. It will be appreciated that when the sliding portion 20 descends, the carbonated arm 40 can also descend and press the carbonated pin 8 (not shown). By force on the pin 8, the gas cylinder 12 passes through a suitable tube (not shown) and syringe 75 (shown in FIGS. 2A and 2B) and in the bottle 45 as described in Patent Document 2. Can release CO ₂ . It will be appreciated that the longer the slider 20 (and the carbonated arm 40) is lowered, the more CO ₂ can be added to the bottle 45 containing water.

Further, the cam surface 70 can push the plunger 52 inward by the action of lowering the carbonation arm 40. Thereby, the valve 50 is sealed and a sealed environment in the system 100 during the carbonation process is ensured. It will be appreciated that the carbonation process can cause pressure to build up in the bottle 45.

Furthermore, it will be appreciated that after carbonation, considerable pressure may be applied to the contents of the bottle 45 containing water. Therefore, when the bottle 45 containing water is removed from the bottle holder 80, if the bottle 45 is immediately released, a "rocket effect" may occur.

According to a preferred embodiment of the present invention, as illustrated in FIGS. 3A and 3B referred to herein, when the carbonation arm 40 is lowered using the sliding portion 20, the protruding portion 25 becomes a recessed region. Can be held in place by 35. This results in mechanical fixation. It will be appreciated that it is the purpose of the mechanical fixture 15 to prevent the bottle holder 80 from tilting to release the bottle 45 until all excess gas has been released from the system 100. Therefore, if the carbonation arm 40 does not rise, the bottle 45 cannot be released from the bottle holder 80.

It will be further understood that the only way to release the mechanical immobilization and thus the bottle 45 is to raise the carbonated arm 40 to return it to the non-carbonated state. By manually raising the carbonated arm 40 (or allowing the carbonated arm 40 to rise automatically via the spring 60), the cam surface 70 can be moved away from the plunger 52, thereby. It will be appreciated that the valve 50 opens and all excess gas is released from the system 100. As described above herein, the time it takes for the system 100 to depressurize may be longer than the time it takes to manually release the mechanical immobilization. Therefore, if the user 5 removes the bottle 45 from the system 100 before all the excess gas is released, a dangerous "rocket effect" occurs. See now with reference to FIGS. 4A and 4B, which illustrate other aspects of the system 100. It will be appreciated that the system 100 also comprises a damper 120. FIG. 4A illustrates a system 100 in which the carbonation arm 40 is returned to its pre-carbonation position, and FIG. 4B illustrates a system 100 in which the carbonation arm 40 is in the depressed position. According to one embodiment of the invention, the damper 120 rotates over the teeth 130 so that the sliding portion 20 and the carbonated arm 40 can rise at a controlled rate after being pushed down and released. Can be installed.

It will be appreciated that the damper 120 can ensure uniform movement of the carbonated arm 40 up to a high position. The controlled uniform movement allows the cam surface 70 to move away from the plunger 52. As a result, the valve 50 is opened so that all the pressure is released by the time the carbonation arm 40 and the sliding portion 20 reach the pre-carbonation position, and thus the pressure of the carbonation process in the system 100 is controlled. Can be released. The mechanical fixation 15 can be released and the bottle 45 can be safely released from the system 100 only when the carbonated arm 40 and sliding portion 20 return to their pre-carbonated position.

It will be appreciated that the damper 120 may be a viscous damper and that the timing of returning to the pre-carbonated position may be adjustable to operate at various speeds.

As described above in the present specification, the carbonation arm 40 may be controlled and raised by the damper 120. Applicants say that if for some reason the excess pressure in the bottle 45 is not sufficiently released due to some failure, the carbonation arm 40 will rise and the mechanical fixation will be released, as described above herein. As such, the user 5 has realized that the bottle 45 can still be removed and a dangerous "rocket effect" can occur.

A typical household carbonation system may include an exhaust valve to release excess pressure from the bottle 45 during the carbonation process and to release excess pressure remaining in the bottle 45 after the carbonation process is complete. Will be understood.

Here, reference is made to FIGS. 5A and 5B illustrating a household carbonation system 200 according to an embodiment of the present invention. In FIG. 5A, there is no accumulation of pressure to be released, and the bottle holder 80 can rotate freely around the shaft 55, which makes it possible to attach / detach the bottle 45 (as described above in the present specification). Illustrates a dormant (pre-carbonation and post-carbonation) system 200. In FIG. 5B, pressure is accumulated in the system 200 and rotation of the bottle holder 80 around the axis 55 is impeded, thus placing the bottle 45 in a fixed position as described in detail below. Illustrates the retained system 200 during carbonation.

It will be appreciated that the system 200 may include all the features of the system 100 and may also include an exhaust valve 210 which may further include an exhaust pin 220. It will also be appreciated that the system 200 may also include a second cam surface 240 that can be attached to the housing of the system 200. When the system 200 is dormant (as illustrated in FIG. 5A), the exhaust pin 220 may project slightly from the exhaust valve 210 and the bottle holder 80 is free about the shaft 55 as described herein above. Can rotate to. During carbonation, excess pressure accumulated in the exhaust valve 210 (before it is opened) can push the exhaust pin 220 outward.

It will also be appreciated that the exhaust valve 210 may be attached to the carbonated head upper portion 250, which may be part of the carbonated head assembly 270 (not shown) of the system 200. Further, it will be appreciated that the bottle holder 80 and the overhang 25 can also be part of the carbonated head 270. As described above herein, the carbonated head 270 can rotate about a shaft 55. The carbonated head 270 may be similar to the carbonated heads described in Patent Document 3 and Patent Document 1, both of which are incorporated herein by reference and assigned to an assignee common to the present invention.

The second cam surface 240 may include a recessed region 230. When the bottle 45 is held in an upright position within the bottle holder 80 during carbonation (as illustrated in FIG. 5B), the exhaust pin 220 may be located above the recessed region 230. Therefore, when pressure is applied to the exhaust valve 210 and the exhaust pin 220 is extended, the exhaust pin 220 can engage with the recessed region 230.

It will be appreciated that while the exhaust pin 220 is engaged with the recessed region 230, the carbonated head 270 cannot move, and as a result, rotation of the bottle holder 80 around the shaft 55 can be prevented. Therefore, the bottle 45 can remain in a fixed position and will not be removed from the bottle holder 80 until sufficient pressure is released from the bottle 45.

When pressure is released from the bottle 45 and the exhaust valve 210, the exhaust pin 220 can recede back to the resting position, thereby disengaging from the recessed region 230 and rotating the bolt holder 80 around the shaft 55. Can be possible (as described herein above).

Although systems 100 and 200 may function independently, it is understood that both of these systems may be embodied within the same household carbonation system 300 as illustrated in FIG. 6 referenced herein. Yeah. By gradually releasing the pressure in the bottle 45 via the normally open valve 50 (as described above herein), the pressure in the exhaust valve 210 can also be reduced, as described above herein. It will be appreciated that the exhaust pin 220 retracts out of the recessed region 230. Therefore, in a scenario where excess pressure remains in the bottle 45 after carbonation due to some system failure and the damper 120 continues to rotate and gradually raises the carbonation arm 40, the exhaust pin 220 has a cam surface 240. Can remain engaged with, thereby preventing the bottle holder 80 from rotating about the shaft 55 and thus releasing the mechanical fixation of the bottle 45.

Therefore, the newly carbonated liquid was introduced by gradually releasing the pressure accumulated in the household carbonation system by the pressurized CO ₂ released into the bottle used in the carbonation process. The bottle can be safely and quickly removed from the household carbonation system.

Although particular features of the invention have been exemplified and described herein, those skilled in the art will appreciate many modifications, substitutions, modifications, and equivalents. Therefore, it should be understood that the appended claims are intended to include all such modifications and modifications as being within the true spirit of the invention.

Cross-reference to related applications This application claims priority to US Provisional Patent Application No. 62 / 016,108 (Filing Date: June 24, 2014), the content of which is incorporated herein by reference. Will be done.

Claims (4)

It ’s a carbonation system,
A carbonation arm having a cam surface and connected to the housing of the carbonation system so that carbonation occurs when the arm is lowered.
A normally open valve, the normally open valve having a plunger that can be pressed by the cam surface during carbonation to seal the valve.
A mechanical fixation unit that secures the bottle in an upright position within the carbonation system when the arm is lowered from the non-carbonated state.
A stepwise pressure release unit that has a damper and operates after the carbonation is completed, and is described until the carbonation arm is raised to a non-carbonated state and the mechanical fixing part is in a non-fixed state. as all of the pressure is released from the bottle, the damper, the said cam surface as normally open valve is openable after away from the plunger, above the carbonation arm in a controlled rate A stepwise pressure release unit that controls the movement to the position ,
The system. The damper is a viscous damper.
The system according to claim 1. A bottle holder that holds the bottle during carbonation,
An axis in which the bottle holder is tilted and rotated to receive the bottle for the carbonation and to release the bottle after the carbonation.
With more
The mechanical fixing portion comprises a recessed area in which the protrusion of the bottle holder is located when the bottle is in the upright position, and the recessed area is such that the bottle holder is lowered when the carbonation arm is lowered. Preventing rotation about the axis,
The system according to claim 1. An exhaust valve attached to a head assembly including the bottle holder, having an exhaust pin protruding from the exhaust valve, and a second cam surface including a recessed area and attached to the housing. further wherein the exhaust pin, wherein the engaging the recessed area of said extended second cam surface from the valve when it is under pressure in the exhaust valve, wherein the bottle holder about said axis To prevent the bottle from being released by rotating to ,
The system according to claim 3.